Abstract: A photoelectric conversion device includes: a first substrate of which end portions are cut off so as to slope or with a groove shape; a photodiode and an amplifier circuit over the first substrate; a first electrode electrically connected to the photodiode and provided over one end portion of the first substrate; a second electrode electrically connected to the amplifier circuit and provided over an another end portion of the first substrate; and a second substrate having third and fourth electrodes thereon. The first and second electrodes are attached to the third and fourth electrodes, respectively, with a conductive material provided not only at the surfaces of the first, second, third, and fourth electrodes facing each other but also at the side surfaces of the first and second electrodes to increase the adhesiveness between a photoelectric conversion device and a member on which the photoelectric conversion device is mounted.

Abstract: A photoelectric conversion device includes a first electrode; and, over the first electrode, photoelectric conversion layer that includes a first semiconductor layer having one conductivity, a second semiconductor layer over the first semiconductor layer, and a third semiconductor layer having a conductivity opposite to the one conductivity of the second semiconductor layer. An insulating layer is over the third semiconductor layer, and a second electrode is over the insulating layer and is electrically connected to the third semiconductor layer through the insulating layer. The third semiconductor layer and a part of the second semiconductor layer are removed in a region of the photoelectric conversion layer that does not overlap the insulating layer.

Abstract: The present invention relates to a film formation apparatus including a first transfer chamber having a roller for sending a substrate, a film formation chamber having a discharging electrode, a buffer chamber provided between the transfer chamber and the film formation chamber or between the film formation chambers, a slit provided in a portion where the substrate comes in and out in the buffer chamber, and a second transfer chamber having a roller for rewinding the substrate. The slit is provided with at least one touch roller, and the touch roller is in contact with a film formation surface of the substrate. In addition, the present invention also relates to a method for forming a film and a method for manufacturing a photoelectric conversion device that are performed by using such a film formation apparatus.

Abstract: A photoelectric conversion device includes at least two photoelectric conversion elements which have voltage-current characteristics different from each other. Further, one of the photoelectric conversion elements has photoelectric conversion efficiency higher than that of the other photoelectric conversion element under the environment in which room light can be obtained. Furthermore, the other photoelectric conversion element has photoelectric conversion efficiency higher than the one of the photoelectric conversion elements under the environment in which sunlight can be obtained. Moreover, each of the voltage of electric power generated in the at least two photoelectric conversion elements is adjusted by one of at least two DC-DC converters corresponding the photoelectric conversion element. In addition, part of the electric power generated in the one of the photoelectric conversion elements is used as drive electric power of the at least two DC-DC converter.

Abstract: Techniques are provided for obtaining a photoelectric conversion device having a favorable spectral sensitivity characteristic and reduced variation in output current without a contamination substance mixed into a photoelectric conversion layer or a transistor, and for obtaining a highly reliable semiconductor device including a photoelectric conversion device. A semiconductor device may include, over an insulating surface, a first electrode; a second electrode; a color filter between the first electrode and the second electrode; an overcoat layer covering the color filter; and a photoelectric conversion layer over the overcoat layer, where one end portion of the photoelectric conversion layer is in contact with the first electrode, and where an end portion of the color filter lies inside the other end portion of the photoelectric conversion layer.

Abstract: In fabrication of a semiconductor device mounted on a wiring board, a semiconductor circuit portion is formed over a glass substrate. Then, an interposer having connection terminals are bonded to the semiconductor circuit portion. After that, the glass substrate is peeled off from the semiconductor circuit portion, and a mold resin is poured to cover the periphery of the semiconductor circuit portion from a direction of the separation plane. Then, the mold resin is heated under predetermined conditions to be hardened.

Abstract: A manufacturing method of a photoelectric conversion device includes the following steps: forming a first electrode over a substrate; and, over the first electrode, forming a photoelectric conversion layer that includes a first conductive layer having one conductivity, a second semiconductor layer, and a third semiconductor layer having a conductivity opposite to the one conductivity of the second semiconductor layer over the first electrode. The manufacturing method further includes the step of removing a part of the second semiconductor layer and a part of the third semiconductor layer in a region of the photoelectric conversion layer so that the third semiconductor layer does not overlap the first electrode.

Abstract: A photoelectric conversion module in which an output voltage defect is suppressed is obtained by forming in parallel over a substrate n number (n is a natural number) of integrated photoelectric conversion devices each including a plurality of cells that are connected in series, and electrically connecting in parallel n?1 number or less of integrated photoelectric conversion devices with normal electrical characteristics and excluding an integrated photoelectric conversion device with a characteristic defect such as a short-circuit between top and bottom electrodes or a leak current due to a structural defect or the like formed in a semiconductor layer or the like.

Abstract: In an optical sensor device employing an amorphous silicon photodiode, an external amplifier IC and the like are required due to low current capacity of the sensor element in order to improve the load driving capacity. It to increase in cost and mounting space of the optical sensor device. In addition, noise may easily superimpose since the photodiode and the amplifier IC are connected to each other over a printed circuit board. According to the invention, an amorphous silicon photodiode and an amplifier configured by a thin film transistor are formed integrally over a substrate so that the load driving capacity is improved while reducing cost and mounting space. Superimposing noise can also be reduced.

Abstract: A photoelectric conversion device having a high electric generating capacity at low illuminance, in which a semiconductor layer is appropriately separated and short circuit of a side surface portion of a cell is prevented. The photoelectric conversion device includes an isolation groove formed between one first electrode and the other first electrode that is adjacent to the one first electrode; a stack including a first semiconductor layer having one conductivity type over the first electrode, a second semiconductor layer formed using an intrinsic semiconductor, and a third semiconductor layer having a conductivity type opposite to the one conductivity type; and a connection electrode connecting one first electrode and a second electrode that is in contact with a third semiconductor layer included in a stack formed over the other first electrode that is adjacent to the one first electrode. A side surface portion of the second semiconductor layer is not crystallized.

Abstract: An object is to provide a photoelectric conversion device in which defects are suppressed as much as possible by filling a separation process region of a semiconductor film with an insulating resin. A photoelectric conversion device includes a first conductive layer formed over a substrate; first to third semiconductor layers formed over the first conductive layer; a second conductive layer formed over the third semiconductor layer; a first separation groove for separating the first conductive layer and the first to third semiconductor layers into a plurality of pieces; a second separation groove for separating the first to third semiconductor layers into a plurality of pieces; and a third separation groove for separating the second conductive layer into a plurality of pieces. An insulating resin is filled in a structural defect that exists in at least one of the first to third semiconductor layers, and in the first separation groove.

Abstract: A manufacturing method of a photoelectric conversion device includes the following steps: forming a first electrode over a substrate; and, over the first electrode, forming a photoelectric conversion layer that includes a first conductive layer having one conductivity, a second semiconductor layer, and a third semiconductor layer having a conductivity opposite to the one conductivity of the second semiconductor layer over the first electrode. The manufacturing method further includes the step of removing a part of the second semiconductor layer and a part of the third semiconductor layer in a region of the photoelectric conversion layer so that the third semiconductor layer does not overlap the first electrode.

Abstract: It is an object of the present invention to obtain a photoelectric conversion device having a favorable spectral sensitivity characteristic and no variation in output current without such a contamination substance mixed into a photoelectric conversion layer or a transistor. Further, it is another object of the present invention to obtain a highly reliable semiconductor device in a semiconductor device having such a photoelectric conversion device.

Abstract: The present invention provides a photoelectric conversion device capable of detecting light from weak light to strong light and relates to a photoelectric conversion device having a photodiode having a photoelectric conversion layer; an amplifier circuit including a transistor; and a switch, where the photodiode and the amplifier circuit are electrically connected to each other by the switch when intensity of entering light is lower than predetermined intensity so that a photoelectric current is amplified by the amplifier circuit to be outputted, and the photodiode and part or all of the amplifier circuits are electrically disconnected by the switch so that a photoelectric current is reduced in an amplification factor to be outputted. According to such a photoelectric conversion device, light from weak light to strong light can be detected.

Abstract: In an optical sensor device employing an amorphous silicon photodiode, an external amplifier IC and the like are required due to low current capacity of the sensor element in order to improve the load driving capacity. It leads to increase in cost and mounting space of the optical sensor device. In addition, noise may easily superimpose since the photodiode and the amplifier IC are connected to each other over a printed circuit board. According to the invention, an amorphous silicon photodiode and an amplifier configured by a thin film transistor are formed integrally over a substrate so that the load driving capacity is improved while reducing cost and mounting space. Superimposing noise can be also reduced.

Abstract: The present invention relates to a film formation apparatus including a first transfer chamber having a roller for sending a substrate, a film formation chamber having a discharging electrode, a buffer chamber provided between the transfer chamber and the film formation chamber or between the film formation chambers, a slit provided in a portion where the substrate comes in and out in the buffer chamber, and a second transfer chamber having a roller for rewinding the substrate. The slit is provided with at least one touch roller, and the touch roller is in contact with a film formation surface of the substrate. In addition, the present invention also relates to a method for forming a film and a method for manufacturing a photoelectric conversion device that are performed by using such a film formation apparatus.

Abstract: In a thin film photoelectric conversion deice fabricated by addition of a catalyst element with the use of a solid phase growth method, defects such as a short circuit or leakage of current are suppressed. A catalyst material which promotes crystallization of silicon is selectively added to a second silicon semiconductor layer formed over a first silicon semiconductor layer having one conductivity type, the second silicon semiconductor layer is partly crystallized by a heat treatment, a third silicon semiconductor layer having a conductivity type opposite to the one conductivity type is stacked, and element isolation is performed at a region in the second silicon semiconductor layer to which a catalyst material is not added, so that a left catalyst material is prevented from being diffused again, and defects such as a short circuit or leakage of current are suppressed.

Abstract: The present invention relates to a film formation apparatus including a first transfer chamber having a roller for sending a substrate, a film formation chamber having a discharging electrode, a buffer chamber provided between the transfer chamber and the film formation chamber or between the film formation chambers, a slit provided in a portion where the substrate comes in and out in the buffer chamber, and a second transfer chamber having a roller for rewinding the substrate. The slit is provided with at least one touch roller, and the touch roller is in contact with a film formation surface of the substrate. In addition, the present invention also relates to a method for forming a film and a method for manufacturing a photoelectric conversion device that are performed by using such a film formation apparatus.

Abstract: A photo-sensor having a structure which can suppress electrostatic discharge damage is provided. Conventionally, a transparent electrode has been formed over the entire surface of a light receiving region; however, in the present invention, the transparent electrode is not formed, and a p-type semiconductor layer and an n-type semiconductor layer of a photoelectric conversion layer are used as an electrode. Therefore, in the photo-sensor according to the present invention, resistance is increased an electrostatic discharge damage can be suppressed. In addition, positions of the p-type semiconductor layer and the n-type semiconductor layer, which serve as an electrode, are kept away; and thus, resistance is increased and withstand voltage can be improved.

Abstract: The area occupied by a photo-sensor element may be reduced and multiple elements may be integrated in a limited area so that the sensor element can have higher output and smaller size. Higher output and miniaturization are achieved by uniting a sensor element using an amorphous semiconductor film (typically an amorphous silicon film) and an output amplifier circuit including a TFT with a semiconductor film having a crystal structure (typically a poly-crystalline silicon film) used as an active layer over a plastic film substrate that can resist the temperature in the process for mounting such as a solder reflow process. A sensor element that can resist bending stress can be obtained.